A laboratory study of seismic velocity and attenuation anisotropy in near-surface sedimentary rocks
A laboratory study of seismic velocity and attenuation anisotropy in near-surface sedimentary rocks
The laboratory ultrasonic pulse-echo method was used to collect accurate P- and S-wave velocity (±0.3%) and attenuation (±10%) data at differential pressures of 5–50 MPa on water-saturated core samples of sandstone, limestone and siltstone that were cut parallel and perpendicular to the vertical borehole axis. The results, when expressed in terms of the P- and S-wave velocity and attenuation anisotropy parameters for weakly transversely isotropic media (?, ? , ?Q, ? Q) show complex variations with pressure and lithology. In general, attenuation anisotropy is stronger and more sensitive to pressure changes than velocity anisotropy, regardless of lithology. Anisotropy is greatest (over 20% for velocity, over 70% for attenuation) in rocks with visible clay/organic matter laminations in hand specimens. Pressure sensitivities are attributed to the opening of microcracks with decreasing pressure. Changes in magnitude of velocity and attenuation anisotropy with effective pressure show similar trends, although they can show different signs (positive or negative values of ?, ?Q, ? , ? Q). We conclude that attenuation anisotropy in particular could prove useful to seismic monitoring of reservoir pressure changes if frequency-dependent effects can be quantified and modelled.
609-625
Best, A.I.
cad03726-10f8-4f90-a3ba-5031665234c9
Sothcott, J.
71ab4088-7b13-46d6-9e28-67538a02d595
McCann, C.
e3bec51c-7d04-47f4-a7bd-1865963e8599
September 2007
Best, A.I.
cad03726-10f8-4f90-a3ba-5031665234c9
Sothcott, J.
71ab4088-7b13-46d6-9e28-67538a02d595
McCann, C.
e3bec51c-7d04-47f4-a7bd-1865963e8599
Best, A.I., Sothcott, J. and McCann, C.
(2007)
A laboratory study of seismic velocity and attenuation anisotropy in near-surface sedimentary rocks.
Geophysical Prospecting, 55 (5), .
(doi:10.1111/j.1365-2478.2007.00642.x).
Abstract
The laboratory ultrasonic pulse-echo method was used to collect accurate P- and S-wave velocity (±0.3%) and attenuation (±10%) data at differential pressures of 5–50 MPa on water-saturated core samples of sandstone, limestone and siltstone that were cut parallel and perpendicular to the vertical borehole axis. The results, when expressed in terms of the P- and S-wave velocity and attenuation anisotropy parameters for weakly transversely isotropic media (?, ? , ?Q, ? Q) show complex variations with pressure and lithology. In general, attenuation anisotropy is stronger and more sensitive to pressure changes than velocity anisotropy, regardless of lithology. Anisotropy is greatest (over 20% for velocity, over 70% for attenuation) in rocks with visible clay/organic matter laminations in hand specimens. Pressure sensitivities are attributed to the opening of microcracks with decreasing pressure. Changes in magnitude of velocity and attenuation anisotropy with effective pressure show similar trends, although they can show different signs (positive or negative values of ?, ?Q, ? , ? Q). We conclude that attenuation anisotropy in particular could prove useful to seismic monitoring of reservoir pressure changes if frequency-dependent effects can be quantified and modelled.
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Published date: September 2007
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Local EPrints ID: 49665
URI: http://eprints.soton.ac.uk/id/eprint/49665
ISSN: 0016-8025
PURE UUID: 67a190b8-cf98-4019-a342-b9058da827f2
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Date deposited: 21 Nov 2007
Last modified: 15 Mar 2024 09:57
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Author:
A.I. Best
Author:
J. Sothcott
Author:
C. McCann
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